This is important to keep in mind when you read articles and/or studies about how electric cars or wind or solar power is impractical. A lot of the data these studies use is just obsolete.
Say you have an opinion piece in a news paper that says that electric cars will always be expensive toys for the rich. It relies on a scientific paper published in a technical journal 2 years ago. The scientific paper does not perform original research but relies on a study published 2 years ago, which study relies on official data reported by companies six months before publication.
Perhaps nobody in this propagation chain meant to mislead. But in the end they are using old data that assumes that battery costs are five times what they are in reality and twenty times what they will be in the near future (for example) and draws all the wrong conclusions.
Similar things are happening with articles and public comments about renewable energy. There are numerous arguments about how we will always need coal power or nuclear power, or natural gas and they all base it on old studies with obsolete high costs of batteries. These articles commit a further error by also neglecting the every decreasing costs of solar and wind power. These articles are even more egregious because while a car lasts only 10-15 years a power plant is supposed to last at least 30 (for coal or gas) and up to 60 (for nuclear). Furthermore, nuclear plants take 5 to 10 years to even build. In those years the costs of batteries and renewables will only go down further.
In the financial press there were many articles about how Tesla will never be profitable, how it is an extravagant way for shareholders to subsidize luxury car buyers, how it will always rely on government subsidies and will need more of them, etc. Well, guess what the federal tax credit expired and lo and behold tesla is profitable.
They weren't necessarily lying. But they were using automotive industry assumptions, and the auto industry with their internal combustion engines is a mature industry with few opportunities for cost reductions. But as far as batteries and electric motors and power semiconductors go ... well we are just getting started on them and hopefully we will have many opportunities for cost reductions.
Yes, using obsolete data from when tech was bleeding edge in 1999 to imply things about cost going forward is misleading.
On the other hand using improvement over the same timeline, drawing a line on a graph and saying "look how X Y is gonna be in Z years" is the same exact type of stupid but pointed in a different direction.
In 1991 lithium was highly immature technology and would take about a decade to make it into fragile electronics. It took another decade to make it into power tools. Now it's viable in high end commuter vehicles. If it was easy to predict the future a decade out with any reliability we wouldn't be having this discussion.
These are not the same kind of stupid. One makes the assumption that costs will always be the same, and the other makes the assumption that cost decreases are linear, or predictable. The former is much stupider.
They are exactly the same kind of error in that both assume stability over time. One assume prices are stable; the other assumes the rate of change is stable.
To be honest this whole debate is a bit academic. In one situation someone is saying "this thing costs a lot of money and so is a toy for the rich". At the time of the statement it's probably true! You might get into an error by saying "it will always be like that because it's expensive now".
But the issue is that, _even at the time of the statement_, the price has been decreasing over time! It's falsifiable at the time of the statement! You don't need to see the future to dismantle that argument.
Inversely, costs have gone down over time for a long time. You could make the inference that there's a floor, of course, and it's reasonable to do so! But it's hard to disprove the claim that prices will keep on going down.
The former is just on its face wrong based on the current facts, the latter is a judgement call about the future. Totally different beasts, and driven from different things.
Both are assumptions about the future. Neither is falsifiable at the moment of speaking. What would be falsifiable is a statement about the historic rate of change.
I agree that it's generally more likely that a 15-year trend will continue than change. If we're talking about a year, that is. But 5 years? 15 years? 100 years? 1000 years? At some point, the general assumption changes.
But without trend data, I also agree that assuming price stability a better general assumption than assuming a major price drop. Historically, very few things keep getting cheaper. It requires a) large society willing to keep making R&D investments, and b) a technological domain with a lot of possible ways to keep lowering costs.
And what I mostly agree with is the proverb, "It is difficult to make predictions, especially about the future."
They'll never be free. They'll never be cheaper than the raw materials that go into them, or the copper to wire them together and into the car.
At some point, there's going to be a price floor that the research, materials supply and competition simply won't break through.
Guessing when that is going to happen is more luck than anything. I do not see it continuing to get exponentially cheaper for long, though.
LiFePho has removed most of the precious metals out of the equation, and the demand for electric cars will continue to compete against the growth in demand for battery storage for renewables. For an analogy, lumber prices have shot through the roof over the past few years where I live due to construction booms. Nothing about the technology has changed, and supply hasn't fluctuated greatly. These same pressures are going to be pushing against lithium batteries getting exponentially cheaper over the next few years. I don't doubt that they will find room to bring prices down, but there is a floor out there somewhere close by.
I wouldn’t anticipate suddenly hitting a price floor, but instead the rate of reduction tapering off, which we’re not seeing yet in a clear way. There’s still a long way to go before we hit the limits from resource costs. And the current rate doesn’t need to continue for long before we start hitting price parity. In some cases we’re already there.
There's a floor but it's not just price of raw materials. It includes performance of same raw materials just used better. So a battery today with X amount of raw materials puts out Y power. A battery in 10 years with the same amount of X raw materials puts out Y^4 power. At least according to E=MC^2 it's a long way before we reach the floor.
Well, the theoretical floor is much further if one goes beyond Lithium. There are various prototypes that oxides aluminum potentially reaching energy densities greater than gasoline. Now, those are currently only reversible in the sense of using aluminum smelter to restore aluminum from the oxidized form. Still we do not know if reversible process is not possible at all in a compact device and the supply of aluminum is vast.
The paper says "We estimate that between 1992 and 2016, real price per energy capacity declined 13% per year". Where do you get your data for the last 5 years?
Regardless, 1 year isn't the correct duration for a bet. People average owning a car for ~6 years, and the average lifespan is something like 12 years.
But depending on terms, I might take a year-over-year bet for battery prices. Demand is high and the pandemic has caused significant supply chain problems. They could well have gone up this year. And indeed, a quick look at news reports suggests key components, including lithium and cobalt, are surging in price. Fine examples of why assuming a historical average has future meaning can get you into trouble.
One kWh of batteries generally requires around 200g of lithium. Both by weight and price it's a crucial, but small component, so unless it suffered a 10x hike, its price isn't relevant.
Meanwhile LiFePO4 batteries, which are currently the most popular chemistry(at least in China), contain no cobalt whatsoever.
Other analysts differ on whether these things will impact the retail price. But you make my point for me: this is an extremely complex problem, and making any simple assumption about future price is a mistake.
If you're coming up to the end of a logistic ("S") curve, then assuming a linear growth (or worse, a fixed rate of increase each year, ie exponential growth) is much worse of an assumption than assuming zero change, if you extrapolate too far.
A first order approximation is always less accurate than a zeroth order approximation for bounded functions, as the first order approximation will have unbounded error whereas the zeroth order approximation will not -- unless you are in the degenerate case of the first order itself being exactly zero. The first order approximation is infinitely worse. Most (all?) things in the world are bounded. Hence if you must choose between just a first and zero-th order approximation, the zero-th order is the way to go for long run predictions. Cue the XKCD comic about the expected number of weddings.
On the other hand, if you are not interested in making long run predictions but only short run predictions, then first order approximations will tend to be more accurate in a small region around the base, but that region might be quite small.
It's about mature and immature technologies. 20 years ago, photovoltaic cells had efficiency ranges in the single digits, but rising. When efficiency rises from 5% to 10%, it makes sense to assume that it keeps rising. But electric heaters had efficiency ranges around 95%, even when my parents were kids. Now they have even better efficiency - 99.8% in my newest apartment - which is only 5% better than 50 years ago - because there is a physical limit.
Technology follows an S curve. First it increases slowly, then faster, then more slowly again. It's silly to assume mature technologies will keep getting better at the same rate and silly to assume immature technologies won't get better. Without specifying the technology, one assumption isn't really sillier than the other - physical limits are unintuitive.
Any electric heater, even those decades ago, was 100% efficient. They turn electricity watts into heat watts. Where is the energy loss? Light? That also becomes heat. Air movement? Also heat. Loss due to heat allong the cord to the heater? Thats heat too. Unless they are emitting large numbers of neutrinos, all electric heaters are simply resistors that perfectly turn electricity into heat.
Put nearly any electrical device in a box, anything from a television to a cement mixer, and it will raise the temperature of the air in that box by exactly the same amount as the watts it draws from the power source. A 500w television puts out exactly as much heat as a 500w heater.
You can't have a wind turbine which extracts 100% of the kinetic energy from wind, because after it there would be a wall of unmoving air, and the incoming air wouldn't be able to get through the turbine.
Analogously, if electricity is carried with the flow of charge - electrons - around a circuit[1], when you extract 100% of the energy as heat, the electrons stop moving and build up in the heater. So you can take the rest of the wiring away because it's doing nothing and save 50% of your costs. Then, a buildup of charge makes a voltage, and a voltage potential difference can drive a current. Therefore you can get 100% of the power out as heat, save half your money on wiring, and use the growing potential difference to power something else. Electricity makes no sense whatsoever.
OK, so that's troll-physics nonsense, but does extracting all the "energy" stop the electrons moving? If not, why not, what energy isn't being extracted? If so, why doesn't that stop current flowing - isn't "free electrons" part of what makes something a conductor of electricity?
[1] though the energy is carried in the e/m field around the surface, somehow
On the other hand, a heat pump bumps the efficiency of your electric heater to like 300%, because it works around the physical constraint. My understanding is that air-source heat pumps are continuing to noticeably improve decade-over-decade.
The commenter was point out the nuance between the two, it's obviously about confidence in an assertion. You just re-reduced it to what was already obvious?
Investing in government bonds vs investing in penny stocks: both are the same thing, as they are both an excess of confidence in predicting the future.
Except when you consider where each technology fits within its own S-curve of adoption (X axis over time, Y axis is % of the technology adopted by the market).
When factoring in the shape of the exponential decreases in costs, and that penetration of most of these technologies is at or before the inflection point (between 5%-15% market penetration), it is more likely that the cost declines will ACCELERATE moving forward rather than slow down.
Why has it felt that laptops and PCs haven’t progressed as much in the 2010s as in the 1990s or 2000s? Because in 1995, there was not a computer on every desk in every home. But now not only is the market saturated with laptops and PCs, people are walking around with mini internet connected “super computers” everywhere they go.
> Except when you consider where each technology fits within its own S-curve of adoption (X axis over time, Y axis is % of the technology adopted by the market).
Unfortunately, even a very small amount of noise in the data makes is basically impossible to know where you are in an S-curve.
Much safer to make predictions based on the far more limited good news that PV+battery is already cheaper than coal for electricity or ICE for cars.
Hmm… question for anyone who knows: with current tech, how much would it cost to develop a significant PV-powered electrolysis-and-Sabatier-process plant in any of the big coastal deserts, for exporting methane?
> how much would it cost to develop significant PV-powered electrolysis-and-Sabatier-process plant in any of the big coastal deserts, for exporting methane?
What are you thinking about as the carbon source? If coal, then this has been commercially viable for decades. In North Dakota there is a 1.5 gigawatt installation running since 1984. That one uses electricity from coal power IIUC, but today PV is cheaper than coal for electricity.
If you are talking about CO2 from direct air capture, the optimistic cost estimates of your CO2 feedstock are around $600/tonne. 1 tonne of CO2 gives ~137 kg of methane at 100% reaction yield, due to the molar weight ratio of CO2 to CH4.
So per tonne of methane produced, the CO2 cost alone is above $4000. For comparison a tonne of natural gas in the US today costs between $500 and $1000 for the end user.
This means that CO2 capture from air needs to become two orders of magnitude cheaper than today before this scheme works out.
I would say hydrogen electrolysis and then liquefaction for large scale distribution/export is way more realistic. This is what the EU seems to be going for together with Northern Africa.
To add to that: I'm not convinced that exporting even renewably-sourced methane is particularly renewable - methane has fugitive emissions when piped etc that are far worse pound-for-pound than CO2.
> Unfortunately, even a very small amount of noise in the data makes is basically impossible to know where you are in an S-curve.
While true, my point is that when combined with the fact that we are pre-inflection point, and the economics now stand on their own (renewables, Electric Vehcile TCO and various Energy Storage applications being already cheapest, competitive or very close too) it is not unreasonable when mapping out the 5-15 year future to bet on an acceleration of cost declines over a deceleration. Particularly because the actual driver of unit cost declines (Wrights Law/Moore's Law) is the doubling / magnitude of units manufactured and put through the system, for which with all the factories being ramped up and planned - point to the positive in my view on it.
Regarding your PV-powered and electrolysis-Sabatier (electrofuel) methane, I think there are two important considerations. In order for methane (or other e-fuels like hydrogen or longer chain hydrocarbons) to be made economically, the capital cost of the equipment needs to be utilized as close to 100% of the time as possible. We already know that PV excess will be centered around the daytime peak (5-7 hours per day) meaning that there would also need to be plenty of excess wind to balance this out to get anywhere close to 100% utilization of the excess energy. Until the electricity grids get sufficiently saturated with renewables broadly, most e-fuel applications will continue to not be competitive, particularly as things like energy storage applications (possibly run off an e-fuel) are likely to be economical prior there being an opportunity for the export of excess e-fuels. That's more at the a end of the S-Curve as far as I can tell.
Build enough PV to generate 24 hours worth of power for the reactor in daylight hours, and store the excess in batteries to power the reactor overnight.
The main argument for hydrogen AFAICT is that it can be exported overseas or stored for inter-seasonal use.
Batteries can't do that, as 1) when compared to literal rocket fuel, they're impractically heavy to put on a cargo ship for bulk transport, and 2) batteries trickle-discharge so after a month or two the battery will be flat.
In fairness, pure hydrogen is also leaky and hard to work with. That’s why I was asking about the economics of turning it into methane… and yet, one of the other replies I got pointed out that methane is also a bit leaky, so we might want to reform it (or whatever the word for “opposite of cracking” is) all the way up to a room temperature liquid.
For example there isn't agreement where on the S-curve fits hydrogen as automotive fuel. Or if it has a future at all. Same with other alternative technologies. The S-curve is only a hindsight device.
It actually is pretty easy to predict the future, in a limited sense, a decade out: the cost of new technologies generally follows an exponentially declining “learning” curve. This has been extremely well studied in the case of the aircraft and semiconductor industries, and is the subject of hundreds/thousands of articles. Of course, some conditions must be met—hence the articles—like plentiful inputs, lack of monopoly power, and government (dis)incentives, but we’d see evidence of these constraining battery tech by now.
The input variable is the cumulative number of units, and of course we can’t be exact about the trajectory of that number, but we can infer from X MWh manufactured -> $/MWh.
Sure. But there’s been questions about the viability of the next node for at least twenty years. If you played it safe and stuck with the current node, you’d have been wrong & at a process disadvantage 14 times out of 14.
No improvement trend goes on forever. But why is this the moment lithium ion hits the wall? It’s like trying to call the end of a bull market.
2nm is just a commercial name. The real features are much bigger, see, for example, https://en.m.wikipedia.org/wiki/10_nm_process. So we are quite far from 10 atoms per transistor.
The biggest problem is lithography. ASML managed unexpectedly for many in the industry including Intel to solve technological problems with extreme ultraviolet sources, but shrinking transistors significantly further requires soft x-rays and the perspectives of that now for mass lithography are much more uncertain than for EUV ten years ago.
And Jim Keller is not a Fab / Processing guy. And if you actually listen to what he said, he is predicting plenty of room to improve, not it will improve every 24 months, which arguably has already stopped happening since ~2017
It has stopped, though. Single-threaded performance, either in absolute value, or per dollar has not been following Moore's law for more than a decade.
And outside of data centers, single-thread performance is still king.
Performance per watt has improved, but that's not a metric the typical end user cares much about.
Single-thread performance is not king though. Software nowadays is extensively multi-threaded. If you're still writing single threaded code for a desktop program people are going to look at you like you have antenna growing out of your head.
And performance per watt absolutely is important. People care a lot about battery life of their laptops and phones and that's strongly dependent on performance per watt.
We'll get to 256 core server chips and that will be the end of the line. You are forgetting that the advertised version number denoted by nm is about what size a theoretical planar transistor would need to have to be equivalent to the advertised process.
Since that number is purely theoretical, we can construct a theoretical scenario in which its theoretical nature would become absolutely obvious. Take a 7nm process node transistor and stack it 100 times. Such a process would be called a 0.07nm process.
I think it boils down to we will hit a wall, but we don't know exactly when we'll hit it. (and how hard, chances are that higher-hanging-fruit refinements will make the transition to stagnancy so gradual that we may not notice at all)
A jump from "all past predictions failed" to "and so will all future predictions" seems rather bold to me. In the end it's like a somewhat upended variation of the "x decades to practical fusion" thing where we all hope that the old joke that x might be a natural constant is eventually proven wrong.
Well, the main direction of refinements at this point seem to be around composable/heterogeneous computing where we basically have a lot of hardware optimized for specific workloads and throw the complexity at the software people. i.e. now deal with GPUs, DPUs, FPGAs, xCPUs, etc. instead of (largely) just a standardized set of CPU instructions.
Except we don't. Where's my single-core 100GHz processor?
Improvements still happen, but not always in the same way. If you implemented an application in 2003 assuming we'd have such a processor you'd be very disappointed. Counting on exponential improvements to continue is risky bet.
Scaling may take us to some strange places, but it's worth noting that an Apple M1 chip has >100x the transistors of a 2004-era Pentium 4, and achieves ~500x the FLOPs at a fraction of the power draw.
Yes this isn't single-threaded performance, but I think we should keep in mind that exponential improvement in price/performance over many decades is possible, if never certain.
There were similar things at the dawn of the jet age. Someone wrote a paper demonstrating that jet power could not improve over propeller power because radial-flow compressors generated too much drag and axial-flow compressors were too inefficient. What the author of the paper didn't know is that, contemporary to him, it was discovered that shaping each blade of an axial-flow compressor like an airfoil significantly improved efficiency. Thus a "physics problem" became a "manufacturing problem"
While it might be the case that today’s EVs will not be economically longer-lived than 15 years, the overall average age of a car in the US is 12 years, and most of my cars have been bought with 10 or more years on them as it makes for very inexpensive motoring (no need for collision or comprehensive insurance, no financing interest, and nearly no depreciation).
I bought my 2015 LEAF new and suspect it will not be economically viable in 2030 while our 2005 Honda CR-V is 16 years old now, still going strong, and most likely will still be in service in 2030.
The 2015 Leaf has the worst battery degradation of any EV. That's Nissan's fault.
However, battery prices are going drop further. Your Leaf has a 24kWh pack. At the current $100/kwh price, thats $2400 for a completely new battery. In the future I'm sure you could get an even higher capacity replacement.
That might have been an intentional choice if they knew either they'd sell to suckers and leave them on the hook for the new battery, or have to subsidize a new battery in 5 years, knowing it would be cheaper, like writing a call on batteries.
The battery had literally zero temperature management, no heating or cooling. They literally could've added a 12 volt chassis fan to make it not suck so bad.
Rapidgate was a thing, the battery heated up when driving, you stop to recharge -> battery heats up even more -> overheat -> limiters engage and you're charging at hand crank levels of power.
The Leaf was built with Japanese climate in mind, where peak temperatures are usually not as high. I always found that strange, given that automotive components are usually tested for outlier conditions.
Is that historical or recent Japanese climate? It's gotten worse lately - Tokyo at 35C 100% humidity is still not Death Valley but it's unpleasant for humans and presumably batteries too.
The main reason the leaf had bad degradation was the 24kwh battery size. People charged them to 100%, drove a good portion of their capacity each day, and cycled the battery often.
In comparison, a tesla could charge to 80%, never drain to below 20%, and charge weekly instead of daily.
Maintenance beyond consumables (brakes, wipers, and tires) costs less than the difference in excise tax ($25 tax per $1000 of imputed value every year). All cars are inspected annually here.
At 4K miles per year (my average pre-COVID), if my risk is average, I’d expect to be in a fatal accident slightly less than once every 22K years. I’m OK without the latest driver aids at that low level of risk.
I have a 10 year old vehicle. The current model has the basic advanced safety features (auto-braking, adaptive cruise control). But, no, I wouldn't get a new vehicle just to get those features. And this is coming from someone who does generally buy new cars.
I expect I’d get more passive safety improvement from buying a 5000# 2011 car/SUV than a 3500# 2021 car/SUV, but if I move my risk from once every 22K (or even 20K) years to once every 25K or 30K years, it’s not clear that’s meaningfully different.
I’d probably be much better off to take less stress at work over car payments and/or lose 5 pounds on an all-risks basis.
Collision avoidance, speed limiting, adaptive speed limiting, adaptive headlights, lane keeping, blind-spot warning, ISO-FIX anchors, far stronger pillars, reversing cameras, lane exit monitors, SOS buttons and GPS reporting, far more air bags, door-cyclist collision warnings, seat-belt pre-tensioning, some have pre-collision suspension raising, etc, etc, etc.
I just went from a 2009 Land Rover to a 2020 Land Rover, so almost exactly 10 years, and one of the the main reasons I did it was safety features. They weren't standard on my model before and they are now. It's night and day.
Also things like eCall (1) that became mandatory a couple of years ago without much fanfare: Fully automatic call/report to emergency services in a serious accident.
I think passive safety of modern cars has significantly improved too - they periodically up the ante on what it takes to get full scores in EuroNCAP for instance (2). A "top rating" car from 10 years ago would probably now be scarily-bad compared to the latest requirements that new models ace.
How do you people leave out ESC - it saved my life at least once or twice and it’s obvious how well they work.
What leaves me even more fumbled is how easily RWD Tesla’s spin out and crash with regen and snow. Take the gas pedal of and you’re going off roading. With normal car you’d struggle to even trigger ESC, let alone loose it.
> What leaves me even more fumbled is how easily RWD Tesla’s spin out and crash with regen and snow.
Where did you get this info from? This is contrary from everything that I've heard from my local Tesla owners group. To the point that they don't even have to swap to snow tires during winter.
My 2005 Honda has ESC (Honda calls it VSA-Vehicle Stability Assist) so it’s probably similar to ABS in these conversations: widely present and not a last 10-years’ addition. I think Toyota had it on all passenger models since 2004.
"271 fatalities and over eight hundred injuries in the United States with more injuries and fatalities occurring internationally" and would have been detected by a TPMS which costs a few dollars.
Underinflation adds to sidewall flexing which increases the heating and wear on the tire, which increases the risk. A few psi isn’t the issue, but seriously under-inflated tires are a safety issue for traction and blowout risks.
I have heard horror stories about the mechanical/electrical reliability of Range Rovers.
The number one complain has been the powertrain. I know the automatic transmission is the weak spot in most vehicles, but I have heard of complete failures before 100k.
I wouldn't own anything else to be honest. I've always driven one, and I also work professionally with a fleet of them and I don't have any problems at all. My last personal one never needed any work at all over ten years. Even if they were unreliable, if it's the kind of form factor you're after I don't think anything really challenges them on the market.
I think they're also a uniquely egalitarian vehicle - if you see someone driving a Land Rover it could be a farmer, a teenager in their first car, a parent doing the school run, an Army unit on exercise, a professional footballer, literally the Queen, or anything in between. You can drive the same car to the rubbish dump and to Royal Ascot and it looks completely appropriate in both cases! I don't think there's any other vehicle even remotely like that.
Collision avoidance is now standard tech. Subaru has been making automatic breaking/adaptive cruise control a standard feature of all new model designs. Legacies MSRP at 22k, and the 18k impreza is due for a redesign in 2022. A quick google shows that the 2021 versa may be the cheapest car with automatic breaking at $16600 MSRP.
My 2008 Outback 2.5XT has Eyesight adaptive cruise control including automatic breaking! Cost me US$6k a year ago with 55000 miles. Thirteen years old!
My 2008 Subaru Outback 2.5XT (JDM model) has camera-based adaptive cruise control, lane departure warning, lead vehicle start warning ("stop looking at your phone"), and pre-collision braking. Also AWD, 265 HP turbo engine. I bought it for NZ$10k (US$6000) in May last year, with 87000 km. https://pbs.twimg.com/media/EnuwXA6VcAAH9MJ.jpg
Time will tell but I've got my fingers crossed that in 15 years time any backstreet garage will exchange your battery on a car of that age for a cost proportionate to the fact that you could reasonably expect another 10 years of trouble free motoring. With luck with a 50% increase on its original capacity.
They already do. A battery swap/refresh/replacement for a Leaf is 5-10k€ over here, depending on how bad shape the original is and whether you want a larger battery in there.
It's kinda sorta doable by yourself, but it's a HVDC circuit so you _really_ need to know what you're doing.
Actual brand-name shops are slowly able to replace individual failed cell packs instead of just swapping the whole battery.
The big problem is that batteries aren't really failing and because of that the manufacturers don't really have a process in place for replacements, each operation is a custom job.
Those are pretty wide error bars, last time I looked at used Leaf's they were selling for somewhere in that range. Admittedly first gen leafs with the 24KWh battery.
> "I bought my 2015 LEAF new and suspect it will not be economically viable in 2030"
Why not? There are already companies who specialize in replacing early-model LEAF batteries with new, higher-capacity ones. By 2030, I imagine this could be a pretty widespread industry - perhaps even rebuilding/remanufacturing OEM battery packs with new cells.
And so long as the battery still works, that LEAF will always be "economically viable" because unlike combustion vehicles, there are practically no ongoing maintenance costs.
Because it will cost around $2-3K for the battery replacement on a car chassis that’ll be worth around $2K to get back to a range and set of features that won’t be competitive with the then-current (no pun intended) EVs or other $5K cars.
If you want to spend $5K on a car in 2030, you’ll have way better options than a 75 mile range, 6kW charging (20-24 miles per hour) 2015 LEAF (CHAdeMO will be fully dead by then and most 2015 LEAFs don't even have it.)
A $5k, 75-mile used EV still offers a lot of utility and value because it will cost almost nothing to run and maintain.
No doubt you’ll be able to buy great $5k combustion cars in 2030, but ongoing fuel and maintenance means their true cost is a lot more than that! And in some parts of the world, increasingly stringent emissions controls mean that combustion cars become more expensive, or even illegal, to drive in cities.
You’re right about CHAdeMO, but anyone buying a 75 mile EV isn’t going to care too much about fast charging anyway. And by 2030, someone may have come up with a retrofit and/or adapter to make old LEAFs compatible with CCS?
A 2018 model 3 or X might be a sub-$5K (in 2021 dollars) car by 2030. If they are, very few batteries will be replaced in old LEAFs. The faster that new EVs mature/evolve, the less comparative value older ones have meaning they will be getting scrapped when the next battery replacement is needed.
I do all the maintenance on our cars (ex- tires, body, and warranty/recalls). The LEAF has already had one battery repair under warranty (at around 17K miles, out of service for several weeks and likely a $2K+ repair at future independent rates-was 2 techs for most of a day plus pages of special sealants and consumables)
Other than that it has needed wipers and windshield fluid and that’s it. If that pattern keeps up, they’re still headed to the scrapyard en masse, I think.
I think there will be a secondhand market offering battery upgrades for older EVs. So they just won't install the exact same battery, but a bigger one or a smaller one (lighter, but same capacity).
10 years of R&D on batteries by some of the biggest corporations in the world should provide some new innovations.
In general I agree with the renewable energy movement, and also with the ideas that come with modern approaches to electric mobility (like car sharing etc).
The only point I have left that I have to agree with, and that's a huge one, is recycling.
Our governments across the planet have failed to enforce sustainable recycling pipelines in the plastics industry, how would this be any different?
Why is my laptop battery useless after a year and has only 60% power capacity?
How is this even legal that warranty for batteries is 6 months?
I think that in order to make more sustainable battery tech, we need better recycling pipelines for it. And more important: all the plastics, chips, and pcbs needed around it need to be 100% recycled, not upcycled. And manufacturs reusing only 10% of their materials aren't worth a shit.
The ironic thing today is that a simple plumbum/acid based battery is more sustainable than a lithium ion one. It's energy density, however, is a joke. But it never gets useless, and is maintainable, and, more importantly, doesn't lose energy density over time so it's ideal for buildings that have a longer lifetime than a car.
> Furthermore, nuclear plants take 5 to 10 years to even build.
But that's the problem.
The cost of solar and batteries is declining rapidly. For how long? We don't know. Exponential curves eventually flatten out. We had Dennard scaling until we didn't.
So the question is, do they get cheap enough before they hit the wall?
We have two choices. Choice one, build new nuclear plants, and then if alternatives are even cheaper, we pay the current/historical price for electricity for a while instead of some lower price (or the investors in the nuclear plants lose money, take your pick). This also gives us new nuclear plants to use to destroy all the stupid plutonium created by old nuclear plants, even if it costs more, and we really do have to get rid of that stuff.
Choice two, we don't, and bet everything that the alternatives get cheap enough before we hit the wall. In which case we're completely screwed if we bet wrong, because it takes a long time to build new nuclear plants, so if we don't start now by then it'll be too late.
They are already cheap enough. Renewables are much cheaper than nuclear and competitive with fossil fuels. We don't need another factor 10 cost improvement. All we need is political will to implement the change. We could be running 70% renewable in a couple of years if we wanted to. To get to 100% we might need to improve the cost effectiveness of power-to-gas facilities, but there is zero reason today not to replace the majority of our energy consumption with renewables.
They're cheap enough when they're not being used as baseload. To get to 100% renewable you would need to pay for storage and then have enough over-supply to deal with extended periods of overcast. That's a lot more expensive.
This is another reason to do both. Use nuclear for baseload and you remove all the storage you would need for solar to work overnight. Meanwhile demand is higher during the day when solar is generating, so still use that there. It reduces the amount of storage you need from the entire night to just the high demand period between sunset and when people go to bed.
> All we need is political will to implement the change.
You only need political will for subsidies.[1] You only need subsidies if it's not actually cheaper.
[1] Or regulatory approval, but let's not bind everything in red tape all around, shall we?
If it is cheaper then people just do it on their own without any government involvement.
Using nuclear for baseload doesn't work economically. Nuclear plant economics are such that you want to run them 100% all the time. Renewables sometimes produce pretty close to 0 energy. If you don't want to invest into storage you need nuclear capacity to cover close to all demand. If you have that capacity you don't need renewables. I don't think we can build nuclear plants quickly enough to prevent catastrophic warming.
If you instead use renewables, batteries, and power-to-gas you can also reach net-zero emissions without waiting twenty years until you have enough nuclear plants. Renewables and batteries are already cheap enough to compete with fossil fuels, and provide enough stability to reach a high percentage of the energy demand. 50% renewables is doable with hardly any storage at all. Power-to-gas can provide the storage needed for seasonal variations, but there are still cost problems with that.
Imo the lack of political will for the energy transformation mostly takes the form of unpriced externalities for fossil fuels. There still is no carbon price that is even close to the actual damages. Damages from the extraction of fossil fuels are not paid for by the companies either. Coal plants still emit tons of Mercury without paying for it. Aviation fuel is essentially untaxed. The list goes on and on.
> Using nuclear for baseload doesn't work economically. Nuclear plant economics are such that you want to run them 100% all the time.
That's what baseload is.
> Renewables sometimes produce pretty close to 0 energy.
Which is why they need storage, and storage is expensive. If you do half nuclear and half renewables, you only need half as much storage.
Less than half, because you can use pricing to shift demand.
Suppose you have 50 GW of nominal demand, but solar generation is at 10% of normal because it's overcast. You can get demand down to 40GW through price incentives. If you had 50 GW of solar which is down to 5 GW, you would need to cover 35 GW from storage. If you had 25 GW of solar which is down to 2.5 GW, and 25 GW of nuclear, you only have to cover 12.5 GW from storage. Less than half as much.
Baseload tends to be about 40% of max load in most grids. i.e. having base production doesn't really change the economics of storage or over-provisioning etc. On the other hand because there is always, in this theoretical grid 60% overproduction potential your base load has real difficulty making money about 1/3rd of the time.
Baseload, is really minimal load in the grid. There are many ways to produce the minimal amount. Real difficult part is to provide the max load demand on the grid.
Basically current nuclear technology is inflexible in economic terms (also quite a bit in practical terms), shown historically by most grid storage being deployed when nuclear was being built out.
Real engineering reviewed a paper that claimed we have cheap enough renewables to do ~80% of electricity from them right now. For the rest 20% we would need massive price drops on the battery side but just that 80% alone would cause a pretty massive decrease in price due to economies of scale.
And for extra points, this phases out oil and coal faster. 1TWh of solar replaces 1TWh of coal, but 1TWh of solar and 1TWh of nuclear replaces 2TWh of coal.
Is this normal where you live (presumably the US)? I find that really wasteful. Cars last twice that in my country, and we have tropical, seaside (salt = rust) weather to deal with.
There's a lot of variation in the US depending on where you live. In California the car can be so old the paint has all come off but there's hardly any rust on the car because the air is very dry, it doesn't rain much, temperature variation is low and salt isn't used on roads. On the other hand you can be places like Canada or the northern midwest where Temperature swings by 100F between summer and winter, salt is used heavily on roads to melt snow, rain is common during the warmer months, and humidity levels in the summer are high. This causes cars, especially those not in covered garages to quickly rust and not last more than 15 years or so before too many components and body frame have rusted away.
And meanwhile, my Highlander will be old enough to drink in a couple years, has lived everywhere from the East Coast to the Bay Area to (currently) the Great Basin, has been taken offroad on multiple occasions, has handled dozens of blizzards like a champ, and (knock on wood) is still hanging in there, even with my rather inconsistent maintenance.
So I'd say a lot of this depends on the model, and possibly the make.
Is there a good way to quickly understand this for any topic?
Like, take something you might not be interested in and just "don't get". Your conclusions will be very quick but based on the current state of things.
The people that "do get it" might be crazy, or they might be seeing a longer trend that they've been following so long that they never articulated it, and aren't even capable of articulating it.
How is one supposed to form opinions on new topics where the state rapidly changes?
There is no easy shortcut. There are some people who have kept up with academic research, commercial developments, and trend lines over enough time to filter out short term noise. Some of them blog or write long comments on HN. But unless you are one of those people yourself, you won't be able to tell which writers are trustworthy.
You can rapidly filter a lot of noise out of energy news with knowledge of physics and chemistry from 100-level university courses (or equivalent) [1]. But most people never acquired this knowledge and a lot of those who have only retained it long enough to pass tests in school. 10 years later they don't remember the difference between power and energy or why some chemical reactions are exothermic and others endothermic.
[1] This knowledge is actually helpful to filter news in general when it makes assertions about the physical world.
> Say you have an opinion piece in a news paper that says that electric cars will always be expensive toys for the rich.
Well, you don't see poor people buying EVs that much. That's car manufacturer statistics, which I believe deserves a good degree of trust.
In the market for new cars, poor people buy cheapest IC cars, but not cheapest EVs.
I will take the point that middle class is now buying budget EVs, but you don't have real economy class EVs selling that well in the West, and in China as well.
Wuling Mini EV will classify as a true economy class EV, but what people lauding it don't say it that Chinese IC vehicles in the same price range outsell Mini EV many, many times over.
> Well, you don't see poor people buying EVs that much.
You don't see poor people buying new cars that much. Which for now is pretty much the same thing as not buying EVs, since almost all EVs on the road are relatively new.
That's starting to change here in Norway. There's a decent amount of used EVs entering the second-hand market. And if you can deal with the short range it's definitely preferable to buy one, since they're way more reliable than on older used ICE.
The other things helping people buy cheaper EVs here is that it's easier to deal with the shorter range since you have fast charging stations everywhere now.
So what needs to improve is:
- More used EVs (just have to get middle class people to buy more EVs and wait 5-10 years)
- Better charging infrastructure (again, get the middle class to buy EVs to help fund the build-out)
- Cheaper EV batteries (again, just get whoever can to buy more EVs, to fund R&D and drive economies of scale)
That's why it's so damaging when countries make EV incentives with caps. Just make it a percentage of the price (or cut all taxes) and don't worry about the benefits going to rich people buying luxury EVs. Increase income taxes on the rich instead if that's a problem. This is like the one case where trickle-down economics kind of work, since buying expensive EVs now makes future EVs and charging stations cheaper.
And I think cheap BEVs will be a HUGE benefit to poor people in the future, since it saves on gas and maintenance costs in the long term.
The other way that EVs enter the market is that someone takes a gas-powered car and converts it to electric. It's not a particularly common thing to do, for multiple reasons. It's time consuming, expensive, and requires tools and space, and a certain amount of expertise or willingness to learn.
The may be a lot of people who have the time, inclination, space, and access to tools to do a conversion but are blocked by the cost barrier. That probably includes at least some poor people. Mostly I'm thinking of young college-age people who might not necessarily be experiencing poverty but also don't have any significant wealth either. Maybe they live with their parents and are having trouble finding work.
I'd like to see EV conversions have the same level of subsidy as OEM cars; that could make it a worthwhile and cost-effective endeavor for a lot of people. It could also provide jobs for local mechanics, for customers who don't want to do the work of converting the vehicle themselves. There are a lot of gas-powered cars on the road. They aren't all worth converting, but some of them are. It seems a waste to replace them all rather than convert the ones worth converting.
There's also a bit of an annoyance w/ EV conversions, at least here in the US: automatic transmissions being pretty much ubiquitous. They're basically dead weight for an EV (which doesn't need to switch gears), and they further tend to have a lot of mechanical and electrical complexity.
I suspect that if I ever convert my Highlander to an EV (which is something I'd like to investigate should its current drivetrain eventually give up the ghost), it'll likely entail needing to remove the transmission entirely (and maybe replace it with a fixed gearbox of some sort?). And given that it's AWD, that complicates things further, since there are very few AWD/4WD EV conversions.
That said, if there are solutions to this problem, and said solutions prove viable, then this makes EV conversion a lucrative business, and opens it up to most cars on American roads.
Transmissions aren't entirely dead weight; being able to switch gears means you can get away with using a smaller motor than you otherwise would. You also don't need to worry quite so much about getting a motor rated for super high RPM.
Converting something with a manual is probably easier than an automatic (especially if there's some software controlling when to shift the automatic based on some engine sensors which aren't there anymore), but there's no fundamental reason why you couldn't just keep the transmission even in an automatic. Especially if bolting a motor on where the engine was is far simpler than re-engineering half the drive train. (You might be able to get rid of or disable the torque converter, though.)
At this point I think the biggest roadblocks to EV conversion are cost and availability of parts so you don't have to design and build everything from scratch. And I think subsidizing conversions would help with both of these. If there's a big enough market, you might even get reasonably priced kits (possibly from the original vehicle manufacturer) that has everything you need including battery boxes and can be installed by someone who's done it before in less than a week.
(Battery boxes are usually the most difficult and time consuming part of a conversion, since they're usually constructed in an ad-hoc way to fit whatever battery you're using into wherever they would fit. Having something that's actually engineered and possibly even crash tested would be great.)
> And I think cheap BEVs will be a HUGE benefit to poor people in the future, since it saves on gas and maintenance costs in the long term.
I’ve been wondering whether the opposite is true. We might find the cost of replacing the battery puts a floor on the price of old EV’s. I wouldn’t be surprised if we are coming to the end of bangernomics.
We already have million-KM batteries, and we're headed toward million-mile batteries.
Even if the battery does die, I wouldn't be surprised to see a lot of secondhand batteries with half a million Ks of mileage put up relatively cheap. You don't need to go straight to brand-new.
> And I think cheap BEVs will be a HUGE benefit to poor people in the future, since it saves on gas and maintenance costs in the long term.
I believe the same, if you race for the lowest cost possible, eventually an EV will be cheaper than the cheapest IC powered car for those exact reasons.
... But as I said above. Wuling MiniEV costs like $5500, which is cheaper than low-end Chinese petrol, or diesel engined sedans priced at $7000-$8000, but is still massively, massively outsold by IC cars in its price bracket despite China's massive subsidies for EVs, and quite draconian curbs on IC powered cars.
In part because the MiniEV has really low range (think first generation Leaf) whereas any IC car is gonna be like a Model 3 at least.
200 miles (on the EPA cycle) really is the minimum for a pure electric car IMHO. 250 miles, really. Otherwise it looks like less of a value than an IC car.
It seems like there should be a removable gasoline or diesel generator purely for range extension. For day-to-day commutes and errands near home, leave the generator at home and save on weight. For long-distance trips, bring the generator with you.
I'm not a free market apologist by any means, but we also didn't see "poor people" or folks in the lower economic strata buy mobile devices and smartphones when they became first available, at least not the scale we're seeing now (without mentioning the fact that the devices were crazy expensive when first launched, adjusting for inflation).
Economy of scale is a thing, and imo it's OK to use the rich and the wealthy as 'guinea pigs' of sorts (which mostly is voluntary as the wealthy are more likely to make riskier bets on new tech than people living paycheck-to-paycheck).
As EV market extends downwards on the economic 'pecking order,' I'm really hoping even more drastic cost reduction and lower barriers of entry into the EV market for folks that are not rich.
An expensive phone is about 500-1000€. A cheap EV is in the 20K neighborhood, and the functionality is pretty bad compared to a cheap second-hand utility car (pretty hard to travel outside your city). Even when regulations push prices up, it's still far more economical to buy a cheap gas car than a cheap EV.
Even in Europe there are plenty of countries where many people can't afford an EV. They can afford second-hand ICE cars. So unless there can be a second-hand market of EVs for about 6K without worrying about the battery, and with a similar functionality of a second-hand ICE car, then yes, EVs will be for upper income brackets.
And I'm not even mentioning that most people lives in apartment buildings, and it's very likely that your car sleeps in the street.
I've seen this discussions around here. People won't buy EVs in the near future because they are expensive, have very low range, you have to have a house, or own a flat (because nobody will pay for a charger installation in a rented flat) with garage, etc.
What people is buying is little electric Scooters. Most of them are <500€ and you can charge em everywhere. It makes sense for travelling inside a city. Spending 20K for not being able to go from Santiago to Madrid, doesn't make any sense.
Nissan leafs are get into the price range and they're basically first-generation mass-market EVs. Yes people do buy these. And in some european cities street-side/lamppost chargers already are a thing. Multiple conditions are only going to get better, not worse.
Nissan Leafs are ~20k for Km0 offers in Spain. They are very limited cars in range, functionality is behind than a 10K Km0 Fiat Panda. Street chargers are scarce, and usually expensive, and I have a hard time picturing a charger in every parking space in my city.
That hardly qualifies as a second-hand market car.
> Street chargers are scarce, and usually expensive
In the past they didn't exist. Today they're scarce. In the future it'll look different. This thread is about trends after all.
> And I have a hard time picturing a charger in every parking space in my city.
We can start smaller of course, it only needs to be scaled up with EV adaoption, not reach 100% penetration immediately. The electric scooters you mentioned would benefit too.
"because nobody will pay for a charger installation in a rented flat"
Where did you get this idea? People pay for an AC, a conciege, a cycle room, a roof terrace, a fucking gardener but they wont pay for a charging point? Also why does it have to be rented?
There’s still a large difference between upper-middle class and upper class. I think many middle class jobs can support owning a Tesla Model 3 or other mid-range new car but not a Porsche.
When I hear “expensive toy for the rich”, I think of a millionaire’s 3rd lambo, not Bill’s Silverado lease. Initial Teslas were sports cars, and now it’s squarely in middle class territory. Still a big improvement and a big market, and in several years, that leads to a good second-hand market and even cheaper EVs.
I think for many (not all, of course) people the problem is not price as much as practicality. I could probably be convinced to spend more for an EV, but without chargers in most apartment buildings and with limited charging networks where I might go, it’s not justifiable yet.
Not when I can buy an ICE and operate for cheaper - note the nearest "charge station" to me is 30+ miles away and then the next nearest is 100+ miles beyond that.
The drop in diesel and gasoline prices recently only cements the value of an ICE vehicle.
It's been a while since I rented a place to live, but charging infrastructure for rentals is a big issue.
You can't buy an EV if you can't charge at home. And you won't buy an EV if you can charge at home if you're not sure you can charge it if you move. (Not to mention if you think you might move to another state, not being able to drive your car there is a question mark)
That’s why I mention practicality! I think yes, for people who strictly buy the cheapest car that’s not bad, it will be some time before EVs are viable.
But many people, including myself, think that EVs are better in general. If I was comparing a $15k car to a $20k car, I could be convinced to spend more on an EV if I was just comparing the vehicles themselves in an ideal environment. But that decision doesn’t make sense until the “practicality” problem is solved.
People buy BMW but they are not the most cost-efficient cars. People buy cars in London , using public transport is cheaper. Cars are prestiege, a point of pride, 'Freedom', an obsession, a place to have sex, and more to all kinds of people.
I can’t disagree with that. I feel like the EV conversation is centered on “richer” countries anyways because of infrastructure and tech. I’d be curious to learn how EVs are being approached in countries which are still developing infrastructure
> I feel like the EV conversation is centered on “richer” countries anyways because of infrastructure and tech.
I'd say EV are making inroads there exactly because of no infrastructure, and tech.
In Vietnam, people choose electric scooters over petrol largely because their maintainance free nature, and no need for fluids, or waiting at petrol pumps.
People like that they don't risk expensive, and lengthy breadown of their scooter when their job depend on it.
They have electric tuk-tuks already. I think batteries / electric motor are inherently simpler to operate, if not fabricate, than ICE so likely to be cheaper at the mass scale. Even solar + batteries + electric motor. And they scale up and down - you can tiny electric things and giant electric things.
US manufacturers still see EVs as a premium option. Batteries are getting cheap, but it's not showing up in vehicle prices.
Jeep has backed off, yet again, from producing an all-electric Jeep Wrangler. They originally announced one for 2020. Then 2021. Then 2022. They shipped some "mild hybrid" things. They just showed an all-electric Jeep Wrangler, but it's a "concept car" only. And, for some reason, has a 6-speed manual transmission.
Even when Jeep was still talking about a 2022 Wrangler EV, it was announced as being available only at the highest "trim level", priced 2X over the base product.
Ford just slipped the electric Ford F-150 to the 2023 model year. "The estimation for the base price is $100,000" says one source. For a pickup truck whose current base price is $28,940. Ford's electric Mustang starts at $61,000. The base gas-powered Mustang is $27,155.
This seems to be a pattern with US manufacturers. Electrics cost 2x the price of the gas model.
Well, this is the argument against EV from the beginning. Literally people were shitting on Tesla because they started with a the Roadster.
Now they have a much, much better car for significantly lower price produced at much, much higher volume.
This is just gone continue, each generation produced will move down market.
Poor people will never buy new cars, but 2nd hand Bolt EV are already a bargain considering what you save on fuel cost.
As more EV are produced, more EV are gone be sold second hand. And at the same time new cheaper EV are gone be interceded in the market.
There is no inherent reason why an EV should be more expensive then a gas car, but there is a 100 year technology and infrastructure gap, this gap needs to be filled by the rich, upper middle class and now the middle class.
This is basically the same with every new mass technology.
Bolts are a bargain right now because of a safety issue so serious it has a STOP-SELL RECALL order, meaning dealerships aren't allowed to sell them until its fixed, which happens sometime this month.
> This is important to keep in mind when you read articles and/or studies about how electric cars or wind or solar power is impractical. A lot of the data these studies use is just obsolete.
My understanding is that phone batteries are extremely different from batteries for large storage. They have vastly different cycle and draw requirements (you can't quick draw on your phone battery). I don't think these studies are being nefarious, but looking at different batteries, where this article is averaging. Reading the article it doesn't give any inclination that they are differentiating these types of batteries.
Yes. A big improvement over the last few decades is rare earth magnets, which have reduced the mass, increased the power and efficiency. (Rare earth magnets in car motors can be and are recycled, FWIW.)
Additionally, the power electronics have improved a lot, too, and continue improving.
As others have noted, Tesla went from their induction motors (which use no rare earths) to a somewhat more efficient combination of switched reluctance and brushless DC motor using some rare earth magnets.
There are also various improvements to rare earth magnets. Magnetic energy density improves somewhat. Cooling schemes improve. Even alternatives to rare earth magnets (certain phases of iron or nickel, for instance) have been and are studied.
I think improvements in cooling schemes is a big part of future improvements. As well as reduction in eddy current losses through better litz wire, maybe playing with the grain structure of the conductor, etc.
Longer term, there's also the possibility of superconducting motors. Although that's mostly for larger scale applications, (near-)room temperature superconductors also have been demonstrated and folks are searching for methods to allow them to work at lower pressures.
So I think there's actually lot of room for improvements beyond low effort prototypes from big automakers. Tesla is doing really well with high efficiency powertrains. There's also the added dimension of integration with reduction gearing (as electric motors like to spin fast).
> The engineers of Tesla motor's shocked everyone when they abandoned the versatile induction motor in Model 3 cars. They used a totally different motor called IPM-SynRM. Let's understand why the Tesla engineers made this crucial design change.
>Hrmm, so the cost and performance is much the same, but it adds value by creating a new talking point for Tesla owners to harangue others with.
I know that hating on Tesla is a thing, but don't forget the higher torque, better efficiency, lower heat generation in the stator windings. And the fact that this type of motor first showed up in the Prius and Tesla made a better version of it. Yeah they're getting away with saying they invented it Prius were touting their continuously variable transmission instead of thier motors.
I'm as big of a Tesla fan as any, but I'm both continuously impressed with how ahead-of-its-time the Prius was and continuously disappointed how lack-luster Toyota has been in pure electric cars. Toyota had like a decade lead on everyone else and just.... sat on it. Only invested in hybrids and hydrogen (which was and is a dead end).
Toyota could've gone all-in on pure electric cars (and better plug-in hybrids than they had at the time) a good decade ago but instead they continue to waste money on hydrogen.... Only now finally announcing pure-electric cars in the US: https://www.theverge.com/2021/2/10/22187113/toyota-electric-...
It's really sad. It's really bad for the climate that they just sat on the Prius drivetrain, which is 95% of the way to a pure electric car, for over two decades (it was released in 1997... it's 2021 right now!).
Literally, people have modded (i.e. added extra battery capacity) Priuses from 2003 to be pure electric even at highway speeds with the same motor and controller. They had everything sitting right there. It's incredibly frustrating.
For Toyota, it wasn't the engineering, design, nor the manufacturing that was the bottleneck. It was sourcing of the batteries.
Toyota sold 100k Priuses it's first year (2005), and peaked at 237k Priuses in 2012. At that time, nobody had the capacity (nor the materials), to produce that many battery packs for full EV use. In hind sight, they could have committed fully to LiIon batteries for the future, but in early 2000s, it wasn't clear at all what technology would actually win. The contenders were, as I recall, hydrogen, rechargeable batteries, and bio-fuels. Toyota had concept vehicles for each of those, and the hybrid-electric was the practical compromise at the time. Toyota, being a large scale manufacturer, could not design a car around a critical component which were in short supply, like LiIon batteries.
Tesla decided to go the rechargeable route, invested heavily in battery manufacturing, and bet on LiIon analog of Moore's Law. Since they weren't going to sell 100k vehicles any time soon, they could scale along the way. Tesla didn't deliver 200k vehicles until 2018. (On a side note, Tesla also had Elon leading it. All of his 'crazy ventures' lead to colonizing Mars. What kind of a vehicle would be most practical on Mars? Not gasoline. Not hydrogen. Yep, EV. And what internet technology is the most practical on Mars? Yep, satellite constellations. What transport technology is the most practical on Mars? Underground tunnels. And so on.)
Currently, all the automakers except Tesla are scrambling to secure battery capacity. Tesla is in a very nice position right now.
Not just that, but Toyota also made the bet that solid-state batteries will be better than aqueous electrolyte li-ion ones, and that they will be available soon. With that assumption, it would be foolish to invest a lot into li-ion battery manufacturing.
Turned out, solid state batteries are much harder to mass-produce than they thought. Supposedly they will have prototype this year.
Haha, I wonder if there is some sort of coin protocol that could be compatible with the deep space network. That latency seems like it could really mess things up.
> how lack-luster Toyota has been in pure electric cars
It's not Toyota's fault, it's a government mandate in Japan. That's why the CEO of Toyota has bashed full EVs in public and why Toyota is the only manufacturer actually pushing fuel cell vehicles instead of going all-in on EVs like everyone else.
From Japan: Strategic Hydrogen Roadmap [0]
> Japan’s Prime Minister, Yoshihide Suga, recently announced that Japan will aim to achieve net zero greenhouse gas emissions by 2050. To decarbonise its economy, Japan is increasingly looking to future fuels such as hydrogen and innovative technology.
> Japan’s Hydrogen Roadmap has an ambitious goal of:
> 40,000 fuel cell vehicles by 2020; 200,000 fuel cell vehicles by 2025; and 800,000 by 2030;
> 320 hydrogen refuelling stations by 2025; and 900 by 2030; and
> 1,200 fuel cell buses by 2030.
> In Japan there are currently:
> 3,800 fuel cell vehicles;
> 135 hydrogen refuelling stations;
> 91 fuel cell buses; and
> 250 fuel cell forklifts.
Basically Japan's problem is two-fold. Their electric network is a 100V system, split to 50Hz and 60Hz sections because of historical reasons. There's no realistic way to build a charging network for electric cars in Japan.
The second part of the problem is that Japan is also heavily reliant on imported coal and natural gas for its electricity production[1] (around 60-70%).
They're betting on Hydrogen fuel cells, because that is the one thing they can produce themselves and not rely on other countries so heavily.
In the early 2000s Chevron bought up the patent rights for NiMH batteries and refused to grant licenses for large batteries. Toyota was sued for patent infringement for their 90s RAV4EV and settled with Chevron.
Supposedly Tesla's early cars used off the shelf lithium ion laptop battery cells to get around these patent issues.
There's some gain to be had in terms of efficiency, but not much. Induction motors are I think generally approaching 90%, and SRIPM-type motors are in the mid 90's.
Probably the biggest gains going forward will be around improving the ratio of power output to weight, and reducing manufacturing costs (of both the motor and the controller). Maybe also increasing maximum RPM and improving durability, for whatever application where current motors aren't good enough.
It might also be nice to have more standardization and modularity. In the EV conversion world, there's kind of a defacto standard of motors made specifically for conversion mostly using a B-face with a 1 1/8th inch shaft with a quarter inch key slot. That helps a lot, as you can buy a motor from one company and a transmission adapter plate and coupler from another company and have pretty good odds it'll work. There are apparently ways to get almost any motor to work with almost any transmission, but that usually requires custom fabrication. (Obviously you can also ditch the transmission and just connect the motor directly to the drive shaft or transaxle or whatever. I don't know much about that route.)
Heat scavenging is probably biggest efficiency gain you can get. Tesla was relatively late to add heat pumps, but did innovate with octovalve (which has like 8 modes of heat distribution, one of which is storing something like 2kwh of heat in battery volume itself).
Note that the impressing 9x% efficiency rates that we hear about are peak efficiency rates. There is something to gain in widening the operating ranges of this efficiency also. See for instance https://www.researchgate.net/figure/Efficiency-maps-of-sever...
what is the cost of the motor vs the cost of the input materials? what % of the cost of a vehicle is the cost of the electric motor? My understanding (however limited here) is that car-worthy motors are still priced at a bit of a premium to their input materials, but it doesnt really matter because overall they are still not that expensive compared to batteries.
Yeah, some motors have rare-earth permanent magnets which are expensive. Induction motors don't, they just have a weird squirrel-cage structure made of (I guess) copper. Probably the manufacturing inputs for an induction motor are cheap, but the motors are a bit inefficient.
I'm currently doing a conversion that uses a Netgain Hyper9 [1]. They cost about four and a half thousand dollars (including controller) and they're pretty bulky and heavy. They're really efficient though. An OEM manufacturer I'm sure could have a motor made much more cheaply and design it to run at a much higher voltage and produce correspondingly more power. I think the Hyper9 just uses magnetized iron or something like that for the permanent magnets. No rare-earths, so it might be pretty cheap to make something like that in volume. They serve the conversion market though, so it's kind of niche product. I have no idea what Nissan spends to make something like a Leaf motor.
In the world where data is new oil, no body is going to give it for free or even for money as they themselves could use it for much higher profits. I assume all news assumptions or data to be wrong and look for after effect evidence that prove that it could be true.
There's a video on YouTube, Gwynne Dyer -- Geopolitics in a Hotter World (2010) ( https://www.youtube.com/watch?v=Mc_4Z1oiXhY ), which very briefly touches on it IIRC. I'm talking about the bit that starts at 8m30s on the video, but I highly recommend watching the whole thing (or at leas the 1-hour talk part - the Q&A is practically inaudible for me).
Basically, the IPCC doesn't publish studies - they study compilations of studies, every 4-5 years. And when they start compiling, they have a cut-off date at the very start and only use studies that have been both completed and have passed peer review from before that date.
Meanwhile, the studies themselves have the same problem - they obviously can't start the study with incomplete data and update the data as they go. The studies need to start with data that finished before they started the study.
And on top of that, they're necessarily a reserved body (Icd say "conservative" but that's ambiguous in politics) - IPCC is run by a bunch of governments trying to figure out the bare minimum of emissions reduction they need to commit to, to not be negligent - they don't want to hear bad news unless it's certain.
The end result is that the data in the report is 10+ years out of date.
The (non political) conservatism is the major issue. They select for conservative non alarmist studies leaving more alarmist ones as outliers, the studies themselves do the same thing.
The compounding effect of this along with the time lag is just so damn disturbing.
I have a similar issue with climate change strategies. The people behind are surely more educated and mentally skilled than I, but I have a feeling they couldn't avoid ignoring false assumptions in the current model, which leads to bad policies and wasted time (and also anxiety).
> There are numerous arguments about how we will always need coal power or nuclear power, or natural gas and they all base it on old studies with obsolete high costs of batteries.
This is simply not true. I'm sure there are some bad articles out there but that's true for anything.
See e.g. https://www.cell.com/joule/pdf/S2542-4351(18)30386-6.pdf where they authors find non-intermittent power production to be necessary even under an assumption of a further 75% drop (from 2018 levels) in battery prices.
> This is important to keep in mind when you read articles and/or studies about how electric cars or wind or solar power is impractical. A lot of the data these studies use is just obsolete.
Solar power and electric cars aren’t impractical because of the price tag of the technology but because of their fundamental properties.
Solar power cannot produce electricity on demand which is why solar (and wind parks) can never compete in a free electricity market where prices are formed based on supply and demand.
A product such as electricity is worthless if it’s all produced during peak hours even if demand is low to moderate at the time or extremely expensive when it’s hardly produced while demand is high. Even if solar and wind parks would cost nothing to build, this problem wouldn’t go away simply because prices are formed by supply and demand which have to be in balance for prices no to fall or jump extremely.
This is the reason why Germany’s electricity costs twice as much to the end user as compared to France and still causes up to ten times as much of greenhouse gas emissions per kWh as compared to France.
As for electric cars: The fundamental problem is refueling time and its geographical flexibility. A car with a combustion engine can be refueled within minutes anywhere on the planet. An electric car has to be refueled for at least an hour and needs to be recharged at a station while an ICE car can be refueled on the right-most lane of a highway if you run out of fuel and someone with a jerry can comes to your rescue.
The fundamental problem with battery electric cars is that energy is changing its form during refueling (electricity => chemical form) which is why there is an upper limit to how fast such a car can be refueled.
For ICE cars, the energy is put into your tank without changing its form which is why ICE cars can be refueled within seconds if necessary (see Formula 1 cars).
This limitation is the main problem with battery electric cars and the reason why you won’t see any large numbers of police or emergency vehicles which are battery powered in the foreseeable future.
There is a reason why solar/wind and electric cars remain highly subsidized in many countries despite of the fact that the technology is becoming cheaper. Both products wouldn’t be able to compete in a free market due to their fundamental shortcomings.
Solar and wind-power can compete very efficiently in a free market. They actually outperform all other forms of energy-production (it is the cheapest way to produce energy). Also every year they get much cheaper.
I would recommend this video: https://www.youtube.com/watch?v=PM2RxWtF4Ds
A bad implementation of something doesn't mean the fundamental idea doesn't work. Germany phased out nuclear not coal for political reasons. There are plenty of examples of grid tier battery projects that have worked wonders with reducing peak demands.
While I agree with you broadly, Tesla loses money on its car business. It was profitable for a full year because of the money it makes from selling carbon credits. That’s not exactly a federal subsidy but it’s not making cars either. So I feel like going at this all angry complaining about imprecision or a lack of focus on details comes off ironic.
This is a common misconception that keeps getting repeated for some reason.
It's silly to exclude the regulatory credit income but then also count things like stock based compensation and capitol expenditures for new factory builds.
Tesla did $1.6 billion in regulatory credits in 2020. Tesla stock based compensation in 2020 was $1.7 billion due to Elon Musk's performance based compensation plan and TSLA skyrocketing. So the car business is clearly profitable.
Then there's the capitol expenditure on building out new factories and expanding their production capacity. From Tesla's 2020 Q3 10Q filing:
> we currently expect our capital expenditures to be at the high end of our range of $2.5 to $3.5 billion in 2020 and increase to $4.5 to $6 billion in each of the next two fiscal years.
They're planning on spending up to $12 billion between 2021-2022 to build out new factories and expanding their capacity. Their car business is clearly profitable, they're just spending all of the money to grow.
Is it a misconception? If the credit didn’t exist they would not be profitable. They lose money on the cars. They sell more cars, they lose more money. I like the company and I like electric cars, but I’m not stupid, I’m not misconceiving anything.
Yes it's a misconception. Their profit margin on cars is consistently over 20%. They have large overhead costs that are more or less fixed like R&D that get amortized more and more as sales go up. They have massive net free cash flow every quarter even while building out new factories that will increase production capacity by 50% every year for the next several years, further increasing economies of scale and operating margins.
You and GP are arguing two different things and are both right.
GP's claim is that Tesla would not be profitable without regulatory credit sales: this is true. Tesla's profit for 2020 is $721M and its credit sales for 2020 are $1.58B, just over double. It's fair to say that, were those credit sales to fall to zero, Tesla risks losing its profitable status. Here we're effectively discussing net profit margin for the company as a whole.
Your claim is that Tesla's automotive gross margin on car sales is 20%. This is also true, but only includes COGS (Cost of Goods Sold), so car parts and assembly costs. It does not include other expenditures such as CapEx or R&D. 20% sounds great (and it is), but when we look at the net profit margin, $721M of profit on $31.54B of revenue gives only a 2.2% net profit margin which is not as impressive.
It's therefore rather unfair to say that GP's claim is a misconception, it's actually perfectly true.
It’s remarkable what energy dense batteries have enabled. Drones and the entire quadcopter scene wouldn’t be possible without them.
Some maneuvers made on a 5” quad can pull more than 100 amps on a 6S, 22V battery. That is around 2,200 watts—more than most consumer microwave ovens! The fact that a battery weighing no more than half a kilogram can supply this much power almost instantly is truly remarkable.
I don’t think modern quads would be possible with combustion engines. They aren’t precise and responsive enough. Modern brushless motors paired with some pretty kickass electronic speed controllers and flight controllers create a pretty amazing thing.
I mean modern quads can fly in “3D” mode and almost instantly reverse the direction of all the motors so the quad can fly in all orientations, right side up and upside down.
Keep in mind that there are exactly a grand total of 4 moving parts in a quadrotor drone. This is the core reason for their success, robustness, ease of use and all.
If all quadrotors needed oil, gas, vibrated like crazy (bad for IMUs), had 100+ moving parts (engine, servo gears, etc...), weighted at least 1-2kg, ran super hot and noisy... we would not have had the "drone revolution".
I guess it's not just about the energy density, but also about how quickly you can convert the stored energy to kinetic energy. Maybe this is something where the modern batteries are much better and combustion engine/generator combo. Parent comment mentions being able to get 2000W out of those small batteries.
you're extolling energy density (energy per unit volume) but your example is about power delivery (energy per unit time). the former is the real progress. the latter just needs low internal resistance, which is a thing we've had.
FYI, the cost of individual cells has long, long gone below $100 per kWh in wholesale volumes.
And believe the cost of a pack itself is very quickly approaching $100/kWh as well if not crossed it already.
Making batteries is still a rather profitable business with double digit margins, it's just latest equipment, and cathode materials became way more expensive, and hard to get than what small battery makers can afford.
Despite China dominating the metallic cobalt supply chain, the cathode materials market are dominated by Japanese chemical companies, and I suspect some form of collusion is there.
With cathode being the most expensive part of the lithium battery cell, it's hard to fathom how a free market price for it can be many times the cost of input materials for years on end.
Collusion is kind of a strong statement. There is a fair bit of competition, its not only China and only Japan, and in these places its not one company. There are cathode companies in Korea as well. There are also multiple cell manufactures in multiple countries.
Tesla on battery day gave a pretty good exploitation of why the price is what it is, and they didn't say 'we need to solve this by trust busting'.
Elon Musk basically said 'if you attach a GPS tracker to a nickel atom its journey would be crazy'. Many, many steps are involved. Many processes, that then need to be reprocessed, and reprocessed again, and reprocessed again with a lot of shipping in between.
The problem is the industry was to small so far to really consolidate all these steps, localize production and mining. Rather many chemicals need are just bought in the form they were available from other industries, and then processed were built on top of that.
Wish I could find one that cheap. The Bosch PowerPack 500 is $900 retail and Specialized recently raised the price of the 600Wh pack in certain bikes to $1300. The price is so silly I pried open my obsolete Specialized pack and just replaced the cells myself.
Mining, and refining is pretty efficient at this point, even when Chinese dominate the market. It's cathode materials which is the single biggest cost point. Cathode materials are dominated by Japanese companies, especially nickel based ones.
LFP is so cheap because making cathode powder for them is a fairly low-tech process with many Chinese garage scale chem companies jumping on it 10 years ago.
Nickel based cathodes are on other hand fairly hard to make with competitive capacities because control of particle size, structure, and shape is a tightly held chemical black magic.
For this reason, I don't expect the new generation of 200WH/kg+ LFP cathodes to be that cheap in comparison to nickel ones.
> Mining, and refining is pretty efficient at this point
Hardly. Nickel goes through a rube-goldberg process of extraction, smelting into pure nickel, made into a sulfate, transported around the world, remade into a nickel carbonate, and finally input into cathode manufacture.
The supply chain simply isn't set up for batteries yet. Nickel metal powder is the best form to transport, and likely the best input for cathode manufacture as well. But the industry formed around the sulfate which was a mature market from other industrial use.
It's one of the more common elements on earth. There is no scarcity. Just cost of extraction.
> -- Cost of processing, refining lithium
Generally dropping. Also batteries can be recycled after their decades of useful life. It's not an expended resource, unlike anything oil based. Otherwise economies of scale apply. It's getting cheaper.
>-- Cost of making battery chemical contents
Non zero. But they last long (decades) and you can recycle. Maybe compare to a gallon of diesel which you extract, refine, and transport at great cost. Then you burn it and lose the ability to recycle it. It's almost obscene how inefficient that is in comparison. So the answer is infinitely better than anything ICE.
>-- Cost of assembling rest of complete battery
Seriously?! I refer you to the latest production statistics of the likes of Tesla, VW, LG and a few other manufacturers that have failed to collapse during the recent economic crisis by virtue of doing a generally great job of growing their business in the middle of a global pandemic. Unlike some ICE manufacturers.
Lithium might eventually be displaced by something better. Better as in even cheaper to harvest, manufacturer, package and leverage. The bar is pretty high at this point.
The biggest win versus something like petroleum is the versatility and commutability.
Let's pretend all of those things have awful trajectories, they don't, but let's pretend they do.
There's different battery tech such as organosilicon electrolytes, zinc magnesium, nanowire gels, sodium ion, there's lots of different ways of battery-ing and as long as you're getting the same electric profile, the devices honestly don't care in the slightest.
Also important to note that in theory a lot of the materials used can be recycled to a large extent. Although it also depends on how that recycling tech evolves, i am assuming it is better than recycling ICE cars ?
I think Lithium is one of the last issues with current battery tech when you compare the additives and support mechanisms for getting the energy out of the battery and into useful work. Cobalt cathodes, Rare earth metals in the magnets of motors, elements like Scandium in light weight alloys, Tantalum capacitors etc. have all more eyebrow raising supply chains.
There will come a point where the economics of Lithium will require looking at, definitely in the scale-up phase. That is probably under 30 years. But there's a lot of lower hanging fruit before the industry collectively properly get onto looking into direct battery chemistry alternatives like Sodium-Air.
Lithium is not scarce. There are other substances in current batteries that are more so. But I know a nickel mine that was founded on a new process and assumed high future prices that didn't work out. They had hard times. You can google Talvivaara. Mostly known as an environmental problem.
Prospectors have found even better new nickel sources since. One is right below a 64 square kilometer nature preserve. After Talvivaara it's quite hard to get people to think it won't have large environmental impact.
There's lots of materials around if you are willing to pay a price for the extraction. Does it make sense, to bet on high nickel prices for the next twenty years?
Non of the materials in the battery are really scares. Building up the capacity both in terms of mining and refining will likely be slower then demand growth however, so in the next 5-10 years its hard to say raw material input prices coming down a huge amount. This effectively generates a lower bound in the mid term for battery prices.
However, its not as bad as it sound. Depending on how you build your battery, the inputs are much cheaper. Iron Phosphate cathodes (LFP) are much, much cheaper. Manganese cathodes are also quite cheap and will be entering the market soonish. Cobalt has already been largely phased out, because it was to expensive.
Beyond that, localization of mining can add a lot of value. Currently a nickel atom travels a long time before it end up in your driveway. So without actually improving mining, a lot of cost can be removed.
There are however huge improvements to the chemical and the manufacturing aspects being made. Over the next decade the manufacturing of the cells will be so fast, that it will be a small part of the cost. Tesla I think is the most advanced in this right now, the assembly lines they presented are quite insane in terms of output per investment. And others are working on things like that too.
There are huge inefficiency still in the chemical processing, both in terms of how it is done, and how much its transported.
Once you get all of those cost out, reaching as low as 30-40$/kwh is achievable even for a high nickel cathode, and significantly less for a LFP battery or Manganese heavy cathodes. Tesla Battery Day target is for 56$/kwh (educated guessing by people) for high nickel but that is for the next 5 years.
There is significant further upside potential even then. Eliminating transition free metals from the cathode would cut cost significantly if it could be replaced with much cheaper materials. This is very active target of research right now, including by a Tesla funded high-reputation university lab.
Removing graphite and increasingly replacing it with silicon and eventually with nothing (using Lithium form the cathode to plate an anode) has a lot of potential as well to reduce cost.
Once we are talking 20 years, Lithium Sulfer is a great candidate both for automotive and long distance planes. These batteries would be incredibly cheap because Sulfer is waste material now.
Lithium is unlikely to go away anytime soon. There are potentially superior materials out there, but lithium has a lot of places to go still.
Also, consider watching Tesla Battery Day and pay attention to detail, they actually do a really great job explaining the costs and how to improve them in the next 2-7 years.
thanks for sharing your wealth of knowledge on EV & power storage, comments like this are why I love reading hackernews :) Now I need to spend a few hours absorbing this information.
Today I bought a new lawn mower, weed eater, and blower, all electric, with batteries, for less than $600 total (not even the cheapest models). They have comparable power to gas-driven models.
Just be sure when using a electric mower you opt for the higher amp batteries. They are also far more limited by wet or tall grass and heaven forbid trying both at once.
Many push mowers will come with a 4amp or higher battery while blowers, weed eaters, and such, use 2 to 2.5amp battery. While the lower amp batteries can work in the mower they will heat up faster and may actually stop if the load they are put under ramps up too fast.
Still even the cost of a 4amp or higher is well worth it to never have oil or gasoline in my garage. Just understand the limitations. I mow a little under 10k square feet which can require a recharge of one or both batteries depending on conditions.
Last time I looked, lawn mowers were not glaring examples of battery driven tech, just like vacuum cleaners. They provided 2-3x less energy output than their wired counterparts, and required charging after just 20 minutes.
I use a range of mowers, and I love the battery one because it is so maneuverable. One battery is enough for my house block. I have a second battery and I sometimes use it for larger areas, simply because it is so light and fast. After 40 mins I'm happy to stop for a beve while the first finishes recharging.
The article says that today a battery pack the size of a backpack and that weighs about 40kg, can power a house for a day. Is that really so? Would that be a normal house, being powered for an entire day? I find it hard to believe that battery would pack that much energy
“The average American or Canadian household in 2010 used about twenty times more than the typical Nigerian household, and two to three times more than a typical European home”
Air conditioning isn't needed in many EU countries except for a few days a year (so it's not worth to even install it in private homes, modern offices mostly have them though for some reason).
Also depending on the country few people use cloth driers - you just hang your clothes on a cable and let them dry by themselves.
Houses in colder parts of EU are also usually better isolated than in US ([1] that's a typical Polish house for example), and more people live in flats in blocks instead of independent houses (so heat loses are vastly reduced because you only have 1 or 2 outdoors walls).
Homes are also simply bigger in US. Average home size (including flats) in my country is a little over 70 square meters. It's probably bigger in western Europe but not by that much.
Also big houses usually have 2/3 stories instead of being very "wide".
And electric heating/cooking isn't very popular, but I think that depends on the country.
It all goes back to electricity prices - in Poland in 1980s most houses had no isolation, everybody heated with coal which had fixed (and very low) prices. Then communism ended, prices were free to change with the market, some taxes were introduced, and suddenly everybody isolated their houses in like 10 years. Otherwise you burned money like crazy.
Given I have skipped last year (due to COVID) but we'd been in France every summer for the previous 5 years and it's gotten hotter and hotter - resulting successive record breaking summers.
I think the decline of the jet stream is a bigger deal for Europe than the US. Hotter summers and colder winters.
Whaha, the Dutch word for insulation is "isolatie". The word "isolatie" also translates directly to the English word "isolation" as in being away from everyone.
House size is basically proportional to the increased energy. The average US home is 2-2.5 larger than European homes [0]. This doesn't just mean more space to heat and cool but also more space for additional appliances.
Probably due to differences in standards, like wall isolation (I don't know the english terms). My house has 25cm isolation in the walls and 40cm isolation under the roof. I also have 3-layer windows and a thick metal door. The ventilation system is isolated and the air heat is reused to save electricity. This is for a 260sqm house.
We average 400-500 in the spring, fall, and winter. In the summer with AC however we'll double that. We are in a northern climate, I have to imagine in the south it gets pretty spendy for AC.
Same reason most Americans are poor. Inability to prioritize long term goals over immediate gains. Save $50 today, but spend $500 more over the next decade.
We have lots of elctric furnaces or heat pumps in the southern and western states where winters are milder. The air conditioning is the real usage. The insulation in new homes is good, but the insulation to keep heat out needs to be in walls as much as ceilings which is harder to retrofit. Modern AC systems help quite a lot and keeping heat away from ac ducting in the attic by insulating them amd adding roof vents and radiant barrier to keep the attic cool. Lighter colors so your south facing wall doesn't fry eggs (literally) also help.
Here in Burkina faso, I use between 5 and 12kwh per day with air con some months taking it close to 15kwh. If the price keeps coming down and with some solar installation, one can leave the grid in a couple of years time
I imagine most of the aircon energy usage coincides with the times of peak photovoltaic generation. So if you calculate by total energy consumption, you'll overestimate things by a huge margin.
You can imagine that, but it isn’t true. AC usage is relatively low in the middle of the day because people let their houses warm up while their at work. It jumps at the end of the workday.
It also looks like a Powerwall 2 costs about $7,500 plus about another $5K for installation.
I use about 20kWh per day--I have a somewhat smaller house--and vaguely looked into whole house batteries a few months back and concluded they would only make sense if I had it wired into just a few critical systems like my furnace. But, at the end of the day, I should still just get a propane-fueled generator at this point if I ever got anything.
So $2K for a battery that can power a house for a day seems almost an order of magnitude off if they literally mean power an entire normal house.
The average US house is not the average house, nor is it representative of normal in the world we live in, which happens to dwarf the US by a factor of roughly 25.
No, no, the world is 25 times bigger than the US, by population. So it's ridiculous to equate houses with US houses, especially when reading a British publication.
The Economist usually takes a worldwide perspective; that's why this article uses US dollars and French kilograms and meters, because those are the most widely recognized units, even though the article focuses mostly on developments in the US.
As for your other comment, that air conditioning and spending US$2000 isn't "representative of the world," I think you will be very surprised if at some point you travel outside the US. The rest of the world does not consist of Elbonian mud farmers as you seem to think. Air conditioning is common throughout the warmer parts of the world; the majority of the world's population has access to air conditioning, though not always at home. The gross world product is about US$17500 per person per year, PPP.
"I think you will be very surprised if at some point you travel outside the US"
I'm not quite sure what prompted you to drag this down to that level. FWIW, I spent several years living in Europe and the Middle East. In homes that weren't air conditioned even. And a fair amount of travel to many other places.
"The rest of the world does not consist of Elbonian mud farmers as you seem to think"
Wow. You have no reason to go there. Fuck off. Saying that lacking $2k of discretionary money to spend on lithium batteries is "Elbonian mud farmers". Wtf. I've certainly had times I my adult life where I didn't have $2k of discretionary money.
Haha! I didn't realize you were imagining a battery bank as some kind of toy. I was thinking more like an alternative to a gasoline generator, which is not really "discretionary spending".
Kragen was right, I was talking about the size of the world. The US is not representative of average or normal. Nor is the UK. And UK publications, due perhaps to colonial history, tend to take a more global view so I would not assume their notion of an average house is centered on the UK either.
Neither is air conditioning representative of the world, or people with a "house" that have $2k to spend on a 40kg lithium battery plus more on the other stuff like inverters, frames, installation. But all are clearly noted in the article as part of the target audience.
Your point still stands, but there's probably some small correction factor necessary since the article seems to be talking about the weight of the cells only.
Although I'd bet the weight of the cells does make up the majority of the mass of a Powerwall, other components might have significant weight. From some quick, cursory research, it seems to have a metal frame/cover and apparently has some kind of liquid cooling. (Also, minimizing weight for a Powerwall seems less important than for an EV.)
Our house uses about 20 kWh a day during the summer, with some minor AC usage in one of the rooms when needed.
During the winter probably about 30kWh, and that excludes extra costs like wood for fireplace.
My house is fully insulated and all windows are double glazed, so that keeps energy usage more efficient. I also have a solar heater (aka "geyser") which lowers energy costs even more. So with that in mind, I really can't believe they're using less than this in Europe...
They might be just using less electricity but other means to generate their needs.
I've heard that the EU has a lot more district heating (which wouldn't show up in an electricity bill, AFAIK) and I'd imagine a fair deal of older buildings have a boiler using oil or gas or something else to burn.
Far north New Zealand, 4 bedroom house, no insulation, no double glazing, electric hot water and cooking. 9-10 kWh/day October-May, ~18 kWh/day June-September (dehumidifier). Wood burner (about US$150/winter) when the heat from the dehumidifier isn't enough to maintain 20 C.
Remarkable. I’m in Sydney, my house sounds similar by description but I have gas hot water and stovetop. My house uses over 5 kWh/day for ambient/idle power alone.
I'm typing this on a 32 core ThreadRipper with 32" 4K screen, which runs 24 hours a day! I also have a Zen 2 laptop and a headless M1 Mac Mini running all the time. And assorted Raspberry Pi, HiFive Unleashed etc. But no TV (or at least it's off).
That's impressive. What's your usage pattern like? I mean, in our house there's regular use of washing machine, tumble dryer, dishwasher, TV's, swimming pool pump. Heck even the swimming pool takes a couple of kWh a day! Would be curious on how to live so frugally.
Sorry if I was unclear. 5 kWh/day of idle. That’s how much it uses when we’re literally not home and all I’ve left on is the networking gear, appliances on standby, etc.
My average actual occupied usage is closer to 20-25 kWh/day, varying mainly by AC load.
A tesla 2 powerwall, weighs about 120 kg and holds about 14 kWh of power.
In India, the average household has a 2.5 kW Peak Power meter and usually, about 10 kWh per day is consumed.
So, not exactly a back-pack, but yeah.
The average individual house in India, is constructed in a plot of about 200 Square Yards. Usually available roof space is about 1000 sft.
Assuming no shadows or high rises in the vicinity (80% of homes have good sunshine even in dense cities), this area is sufficient for about 5 kW of installed capacity.
Most of the deccan plateau gets about 6 hours of good sunshine year-round. So that translates to about 30 kWh of power generation capability.
So, a 3 kW installed capacity, with 1 powerwall will be sufficient to power an average household for most of the year.
Of course, this does not take into account usage of ACs (a fast increasing power consumption category in India)
However, it costs about Rs. 100,000 for 1 kW of installed capacity (including inverter and grid connected meter, no batteries) For 5 kW, that is 500,000 Rs. (about 7000 USD) of investment.
Average annual salary of an Indian household in an urban area is about 15000 USD. About half of that in rural areas.
If there are good financing options and grid connected reverse selling meters (they are being encouraged by many local and state governments), there could be a revolution in installed solar capacity and utilization.
Very much depends on the home. Tesla Powerwall 2 seems to be 13.5 kWh at 114 kg. Energy consumption can be anything from 30 to 40[1]. So one Powerwall 2 unit probably won't get you through the day if you use that much.
Getting you through the day is not really the point though.
The point is
1) shifting some
consumption during peak hours off of peak rates
and
2) having backup to get you through a limited outage, not necessarily at your full normal consumption level but without having to be in the dark / without internet / without phone and possibly car charging.
Nobody should evaluate this by whether one battery pack by itself provides all the energy anyone needs for everything with no limits. It’s one component with several good use cases.
I’m not sure about regulations in the US but in The Netherlands you cannot just attach a battery and think you are independent of the grid. To protect the net and people working on the net, power sources behind the meter must disengage when the net/mains power drops. This effectively disables your independence plan. If you want to be independent you have to get some expensive mechanism installed that will decouple your house from the net in case of net failure and bring it back when the mains is up again. And you need get it certified periodically.
So unless you have enough generation to completely decouple from the net you are not really independent or it will cost you.
Okay. Perhaps I used the wrong sources when I researched what it would take to be able to handle outages. The costs for the installation and periodic “transfer switch” were significant, moreover because doing it as a private individual instead of a company was hard to arrange.
I agree with what you said but it seems you may have meant to reply to a different comment. Independence is another topic, certainly related somewhat, although it didn’t come up in my comment... interesting nonetheless.
Actually I did. I interpreted the limited outage from point 2 as the supplier not being delivering power for a short period. If that were to happen in a normal situation here the regulation says your sources have to cut off as well. Unless you install some additional gear.
So without additional Equipment just having solar and a power wall wouldn’t help during outages.
Another anecdote: I rent a 50m^2 apartment. Electricity consumption for the apartment, averaged over trailing 12 months, is 4.5 kWh / day. This excludes: energy for stove top/oven (natural gas) and energy for hot water (paid for as part of rent, cannot see the details). Consumption for two people, including one person working from home full time. Relatively modern apartment that is warm enough in winter without active heating.
This will not be representative of energy usage in houses, larger apartments with many exterior sides & lots of exposed glass.
edit: house prior to that was an older 100 m^2 semi-detached house with much worse insulation. Similar setup with natural gas for cooking & hot water. Annual electricity consumption was 1750 kWh / year so about 4.8 kWh / day on average, for two people. Not so different to the current situation. Curious. From memory we ran the air conditioner on a few days in summer and electric heating in the depths of winter. From memory the house was somewhat unpleasantly cold some of the time so perhaps we tended to put on warm clothing rather than try to heat the whole place.
That sounds reasonable. My house is about twice your size and so is my electricity consumption (8.8 kWh/day last billing cycle). Also doesn't exclude stove/oven/hot water as these are all powered by natural gas.
I was shocked by a few other comments saying 30 kWh/day. Is it because they use electricity to cook and heat water?
: user@host:~; units
2529 units, 72 prefixes, 56 nonlinear units
You have: 40 kg * 0.6 MJ/kg
You want: MJ
* 24
/ 0.041666667
(The 13.5 kWh in 114 kg tyingq cites for a Powerwall 2 in https://news.ycombinator.com/item?id=26682770 works out to 0.43 MJ/kg, which includes some power electronics as well as the batteries themselves. The US$12500 price ghaff cites in https://news.ycombinator.com/item?id=26682837 works out to under 4 kJ/US$, or US$925/kWh, which is a terribly high price even for lithium-ion.)
24 MJ would be 1 MJ/hour for 24 hours, or 3 MJ/hour for 8 hours, about 300 or 800 watts, respectively. Some houses use much more than that; others use much less. If you're looking at your electric bill, 500 watts would be about 370 kWh per month:
You have: 500 watts * 1 month
You want: kWh
* 365.2422
/ 0.0027379093
40 kg of lithium-ion batteries are indeed roughly the size of a backpack (≈20 liters), though I wouldn't call it a small backpack. Around here, the retail price for the batteries would probably be closer to US$2400 retail than the less than US$2000 they cite, but that's not an error in their calculations; it's just that they're using a lower price of US$140/kWh.
The article claims that in the early 01990s this quantity of batteries would have cost US$75k. I'm pretty sure this is wrong. This quantity of lithium-ion batteries might have cost US$75k, but even today lead-acid batteries cost half what lithium-ion batteries do.
I don't think the price of lead-acid batteries has changed that much over the last 25 or even 50 years, though admittedly I don't have any 30-year-old battery catalogs to check pricing in. Lithium-ion batteries in the 01990s would have weighed only a little more than lithium-ion batteries today, so it looks like they're using the pricing of lithium-ion batteries and the weight of lead-acid batteries.
If you're powering your house from batteries, you should probably do it with lead-acid batteries, not lithium-ion batteries. The big disadvantage of lead-acid batteries is that they weigh roughly three times what lithium-ion batteries do (per joule), so lead-acid electric cars had roughly a third the range of lithium-ion electric cars. But the weight is not enough to matter for a house.
There is enough lithium in Earth's crust to power the world economy through the night. There is, I think, not enough lead. So although lead is currently cheaper, lithium is more scalable. Other less developed candidate options include sodium batteries and aluminum fuel cells.
Nickel-iron batteries might be even cheaper, though I'm not sure, and they're definitely more scalable. Nobody sells them anymore, though lots of telecom centers still run on them.
It's unfortunate that the article cites a power capacity, "1.2 gigawatts-worth of storage", but not an energy capacity, for the US's utility-scale storage rampup last year. 1.2 gigawatts for five minutes would be 100 MWh, in the quaint units used in the energy markets; 1.2 gigawatts for 12 hours would be 14'400 MWh. There is a very significant difference between these; one requires 144 times as much battery behind it than the other. By contrast, the difference between 100 MWh over 5 minutes (1.2 gigawatts) and 100 MWh over 12 hours (0.008 gigawatts) is mostly a matter of what shape the batteries are and how much active cooling is needed. One wonders if this is not simply an error because the author did not know the difference between gigawatts and gigawatt-hours.
40kg translates to 4-9kWh depending on the chemistry, meanwhile houses in the UK draw around 3kWh/day averaged over a year so unless a house is woefully inefficient, it checks out.
3kWh seems way too low. We consumed on average 7.3kWh/day. According to our energy supplier this was on the low side for our house type and family size.
Really? Houses in the US draw 10x on average relative to the UK? That seems unlikely.
ADDED: I can believe there's some difference because of AC but I basically don't have AC (just one window unit I run a few days a year), have oil heat, and have a somewhat smaller than average house but I still use about 20kWh/day.
My highest months come out to less than 10 kWh per day. This is work from home + running the furnace (blower and pumps) and running a humidifier. Lots of months will be less than 200 KWh total.
This is a medium size house in a colder region of the US.
Do you have an electric hot water heater? That would probably boost my use a lot.
I wonder if your house is smaller than the world average or even the UK average? It probably has less thermal mass than the UK average. What are you spending your 800 watts on?
My Silicon Valley house consumed ~450kWh/month (15kWh/day) (before we bought an EV) which is very much on the low side from what I see here. 1100sqft. No A/C. Rarely run the heat. Every single light in the house is an LED. Gas appliances. 2 people, not home during the day.
Your neighbour is stealing power. 15kwh/day means you are permanently using 600 Watts. Do you have a stationary (desktop) computer? Or do you underestimate heating. You can burn through your whole years budget easily in less than two month. What about the oven, I mean do you bake?
Sounds about right. My house, at idle, uses 300w last time I measured it, probably more now. Most of that would be electronics. A rack in the garage with a 24 port PoE switch powering a couple of APs, and a router, a NAS, a handful of small devices, plus whatever drain is used by the various laptops and iMac at sleep, and the clocks on the various appliances, the small aquarium pump on the cat fountain.
The appliances, as I mentioned, are all gas, but still a clothes dryer and a washing machine consume some electricity, as does the pump on my furnace, as do ceiling fans in use when necessary.
And of course, the devices that cycle on and off all the time; the refrigerator, instant hot tap under the sink.
And then there's the actual electricity we consume during the times we're home to do things like light the house, watch television or use computers, listen to music, etc. It is quite easy to use 2000-2500w when home and active in the evenings.
He did say gas appliances which I assume would include the oven and might include a dryer. Presumably not the refrigerator though (there are propane refrigerators but you wouldn't normally get one if you have electricity). I probably draw 400-500 watts even if I'm traveling.
A decent refrigerator should consume less than a kWh per day, perhaps 1.5 kWh/day for refrigerator + standalone freezer - this is something that has changed over the last couple decades, at least in the EU there has been a strong push towards more efficient appliances and refrigerators consume much less power than older models.
This does not make it more likely that someone is stealing their electricity than they have a refrigerator and/or freezer making up the rest of their unspoken for electrical bill.
The 3kWh figure for UK is just electricity - add 12kWH for heating energy from gas to get a more reasonable number given that people in the UK generally don't live in shacks.
Yes, although the 30 kWh US figure doesn't include a lot of gas/oil heat in the North/mountains either. (It does include a lot of AC but average electricity consumption is still a lot higher apparently in the US even taking that into account. I assume bigger houses is one reason.)
I think in the US it's common to heat and cool badly insulated houses with electricity, whereas in europe almost nobody cools, heat comes from other sources and insulation is taking way more seriously, especially for anything built recently.
The best way to reduce your energy bill (whichever source) is to live in the right climate zone I guess.
Electric heat isn't super common, especially in standalone houses, in areas where you need a lot of heat in the US. I don't know the numbers off the top of my head but electricity costs a lot more than gas or oil. You're right about the AC but I still use 20 kWh even with no AC (and no electric heat).
Thanks for the insight. I vaguely remembered that people run the ac in reverse for heat, but that is probably only in paces that almost need no heating.
- AC is a very common consumer of large amounts of electricity (depending on the region, many regions will have almost no AC while other regions will have it in every building running almost constantly)
- Electrical heat is not the most common form of heating, but it's been growing a lot and is also a big consumer when it is used
- Laundry Washer/Dryer are pretty large consumers (mostly the dryer)
- Water heaters are often electrical
- Electrical ovens and stove ranges are pretty common, which
can pull quite a bit depending on how much use they receive
AC is a big one. Where I live in New England, we usually have a couple spells where I really need to turn on my office window unit for a week or so. Those months can drive my electricity consumption up by 200 kWH or more for the month--and that's just one small window unit run intermittently during the day to cool one small room.
(electric tumble) dryers are an interesting point. They're getting more common, but most people I know in the UK either don't have one, or have one but don't use it for normal washes (they use a washing line or a clothes horse).
AC is extremely efficient for what it's doing, but it only works because the temperature difference is relatively minor. Where they can get away with it, they use something similar to AC for heating in the US.
But it doesn't work everywhere for heating. Consider that even in the hottest climates in the US, you're cooling your air by 30 degrees. But in the coolest climates, you're heating your air by 60 degrees.
My sister has this system in Philadelphia, but when it gets cold enough the more inefficient raw electric heating kicks in, and that really chews through electricity like no other.
Not really. My electricity usage is considered normal so I've never really looked into it.
Additional freezer, washer & dryer, oven (I have a propane range but many do not), microwave, there's some additional water heating in the dishwasher as well as for drying, TVs, other electronics like printer stereo etc., furnace/water heater are oil but still have pumps etc.
"AC in reverse" I'm assuming means a heat pump, which is very common in the US except for the parts that get really cold like the Northeast and Midwest. They are very efficient down to a bit below freezing, but will result in higher electricity usage since you are using electricity instead of a different fuel.
I don't think anything is "going on" given that my consumption is about average for my area. I do have 3 fridges which are all pretty old at this point which is certainly some ongoing load. I also have at least the usual number of electronic devices consuming at least standby loads. Then there are the usual intermittent things like electric dryer, dishwasher, etc.
1 KWh/day for Fridge. Lights should do less than 0.5KWh/day. Washing machine is maybe 0.3KWh/day. Maybe, other electronics might add up to 1-2KWh/day. Cooling is not required most of the year. Maybe fans for a couple of months. Heating is separate (EDIT: UK figure), as others have noted.
Heating, which can easily be 5 kW, 120 kWh/day; many US houses are heated electrically, so it's not always separate. Air conditioning can easily be 3 kW, or 72 kWh/day, although it's usually only on during the daytime, so figure 30 kWh/day; it's common to run a 240 VAC circuit in the US for the air conditioner because the 2.4 kW of a standard 120 VAC 20 A circuit is insufficient. Incandescent lights could easily be 1 kW (which you get to offset against the heating part of the year), which is another 24 kWh/day.
A household stove is usually about 4 kW if you're cooking on two burners, but you're probably only cooking about 2 hours a day, so that's 8 kWh/day if you cook at home. (Some people cook with other fuels, but others use electric stoves.) Hot water heaters are also a few hundred watts, I think; an on-demand tankless hot-water heater is on the order of 3 kW, but in the US hot-water tanks are far more common, constantly leaking heat through their fiberglass insulation.
In Arizona and New Mexico, where I grew up, common inefficient houses need air conditioning during the day and heating at night much of the year.
So it's easy to see how, even if cooling is not required most of the year, you could easily use 50 kWh/day of electrical energy in the kinds of huge houses people have in the US.
Heating isn't separate for me. For me, cooling isn't required most of the year (probably similar to UK weather), but for many parts of the US cooling is required almost year-round.
I recall the first time someone showed me lithium batteries, in a radio control car that outperformed a real car. Even then, the price while high wasn't the biggest barrier to getting large quantities; you just couldn't get as many as you wanted. Don't think that has ever eased.
I think that's why TSLA is such a hot stock, people feel there's much more market thats undeserved and TSLA seems to be the only folks gearing up to build batteries until everyone has all they want.
Great progress. Still the lithium chemistry energy density is nowhere near what is needed for flight and heavy traffic. We are at 200-400Wh/kg and we need 2000Wh/kg.
I wish I could buy at this price. Maybe for some large manufacturers. If one is shopping for eBike batteries privately for example the price is sky high comparatively.
I wonder how much there is left to reduce costs? 98% cost reduction for physical chemical products is pretty good. And many additional gains are likely increased complexity...
We need to go a lot lower. Prices are still high for retail investor. Was just quoted $16K for an LG 16kwh matter. That’s $1k per kWh after installation costs. And a 16kwh battery doesn’t even supply my house with 1 day of power.
The thought exercise I most would like the answer to is: how much of this (that is batteries and solar/wind) could have been advanced in the 50s and 60s if the petrol companies weren't, uh, redirecting investment. Was the transistor or imaging or key materials engineering needed to enable modern batteries and solar five decades earlier, or was there just a lack of real funding?
It doesn't seem too clickbaity. $73k/$75k = 97% (assuming the figures are correct). Knowing that the weight is reduced is good, because the weight determines where the batteries are useful; no matter how low the price per kW h goes, if the kW h/g is too low, the battery isn't going on a spaceship.
Were lithium batteries really that popular in 1990? I would think think that they were just starting to get popular so that would make a lot of sense.... but in the last 10 years the price probably didn't change that much.
“Armed with Gore's utility bills for the last two years, the Tennessee Center for Policy Research charged Monday that the gas and electric bills for the former vice president's 20-room home and pool house devoured nearly 221,000 kilowatt-hours in 2006, more than 20 times the national average of 10,656 kilowatt-hours.”
It's about 27kWh/day, and according to the stats in the link fv6 provided elsewhere in this threadset, that's average for a northeast US house. Houses in the south tend to use more like 15-16k kWh/year, due to air conditioning mostly, leaving the 2015ish national average for single detached homes closer to 13k kWh.
This post has been an interesting eye-opener for me. Somehow I've never really thought about the numbers deeply, but, having a 100-watt lightbulb on for 8 hours is almost 1kWh. My and my partners' computers + home server, at a mix of wattages and uses but mostly left on a lot, are probably using 15-20kWh daily. That's... a lot of power.
Most computing devices are more efficient that they used to be, although there are more of them. I'm reminded of this because I keep my house pretty cool in the winter and used to be my office was relatively cozy even so because of all the heat being thrown off by big CRTs and tower systems under the desk. It's much less so today.
Here in Norway the average is 16k kWh a year[1], or about 44kWh a day, but then most uses electricity for heating, hot water etc and it gets fairly cold during winter.
10k kWh per year roughly corresponds to consuming a constant 1kW/h which sounds about right, if not a bit high, if you exclude heating. But I don't think electric heating is common in most places.
lithium is just cheap because it wrecks some 3rd world countries natural resources. If they'd slap the price of recovery times it will need to regrow nature in that place, it wouldn't be as cheap.
The majority of lithium in battery comes from West Australia. Its fairly conventional hard rock mining.
There are some environmental concerns in the production of lithium carbonate from evaporation ponds in deserts of South America. However to say that it 'wrecks' 3rd world countries natural resources is a bit of an odd statement.
The only real issue is that evaporation ponds use water from underground aquifer. This is very salty mineral rich water and the water use is not as high as farming would be and there is a lot of these aquifers.
In the future, as lithium consumption growth much of the growth will come from more hard rock mining in mostly first world countries, clay mining (unlimited amounts all over the world) and direct lithium extraction (gigantic amounts of extraditable lithium in aquifers all over the world) from aquifers where the water is pumped right back, just with half as much lithium in it.
Evaporation ponds are basically a legacy technology and the boom in lithium will likely mean that they are gone be phased out over the next couple decades in favor of DLE.
Bolivia. The US-backed coup against Evo Morales may very well have been in part because of his intention to implement state control of lithium extraction, preventing foreign companies from ransacking the country's natural resource. https://www.humanrightspulse.com/mastercontentblog/bolivian-...
You shouldn't believe every conspiracy theory you read.
Basically one guy claimed lithium is the reason for a US backed coup. This is not proven and most expert don't believe this is true. Its neither proven that it was a US backed coup, and even if that was proven, lithium is very, very unlikely to be the reason.
Lithium is not gold or oil, lithium is everywhere, the reason you produced in this region of South America is because it is cheap to let the sun do a lot of the work. But the reality is, its still more like a complex chemical, more then a metal. The technology to refine it and get it to the grade needed to be valuable, is very difficult, and the outlandish claims made by the president about the government doing all of this extremely advanced processing (and even build cars) were simply political BSing.
It seems what is going on her is that a president made a lot of claims about the value of this resources, over-hyped its value and potential, and when opposed claimed lithium is the reason and its all the evil US fault. This is what I would call narrative building.
Lithium projects are happening literally all over the world, the waste majority of expansion of supply is not happening in South America anymore. If Bolivia ever wants to make real money from this resources they need foreign company that have DLE technology do it and tax them. With DLE much less manual work is required so it will not be an industry that creates massive amounts of jobs.
> salt flats that stretch across Chile, Argentina, and Bolivia and hold over 75%
This is flat out false.
> Bolivia’s Salar de Uyuni salt flat alone holds an estimated 17% of lithium globally.
I live in Chile so I know a thing or two about mining. 20% of fiscal income stems from copper exports and the majority of that from the state owned mining company Codelco.
There are many mining operations of foreign companies which don't generate nearly as much fiscal income so putting mining under state control is completely understandable. This is exactly how we and oil countries got rich. We destroy the environment so at least we should be compensated instead of exporting profits as well.
A US-backed coup against Bolivia makes no sense, Chile is a muppet and does whatever the US needs done. There is no need to intervene in Bolivia if you can just ask Chile to expand lithium mining and we will happily do it.
I have seen the lithium mining sites in Chile, compared to copper it is clean. The mining operations are still small in comparison to copper and investment is slow.
Say you have an opinion piece in a news paper that says that electric cars will always be expensive toys for the rich. It relies on a scientific paper published in a technical journal 2 years ago. The scientific paper does not perform original research but relies on a study published 2 years ago, which study relies on official data reported by companies six months before publication.
Perhaps nobody in this propagation chain meant to mislead. But in the end they are using old data that assumes that battery costs are five times what they are in reality and twenty times what they will be in the near future (for example) and draws all the wrong conclusions.
Similar things are happening with articles and public comments about renewable energy. There are numerous arguments about how we will always need coal power or nuclear power, or natural gas and they all base it on old studies with obsolete high costs of batteries. These articles commit a further error by also neglecting the every decreasing costs of solar and wind power. These articles are even more egregious because while a car lasts only 10-15 years a power plant is supposed to last at least 30 (for coal or gas) and up to 60 (for nuclear). Furthermore, nuclear plants take 5 to 10 years to even build. In those years the costs of batteries and renewables will only go down further.
In the financial press there were many articles about how Tesla will never be profitable, how it is an extravagant way for shareholders to subsidize luxury car buyers, how it will always rely on government subsidies and will need more of them, etc. Well, guess what the federal tax credit expired and lo and behold tesla is profitable.
They weren't necessarily lying. But they were using automotive industry assumptions, and the auto industry with their internal combustion engines is a mature industry with few opportunities for cost reductions. But as far as batteries and electric motors and power semiconductors go ... well we are just getting started on them and hopefully we will have many opportunities for cost reductions.